JP2001513314A - Circuit for selective power supply to electrical unit - Google Patents

Abstract

A circuit is provided for selectively providing electric supply voltage from an input feed line with a neutral conductor, a phase conductor and optionally an earth conductor to individual or parallel-connected groups of connected terminals each comprising a phase core, a neutral core and optionally an earth core, to which electrical units using electricity, for instance light fittings, are or can be connected, which circuit includes: a neutral connection between the neutral conductor and each neutral core; optionally an earth connection between each earth conductor and each earth core; a phase connection between the phase conductor and each phase core, in which phase connection is arranged a current control element; and an overcurrent safety element, for instance a fuse, which is incorporated in each phase connection and which limits the current to the maximum value determined for the relevant phase connection.

Description

DETAILED DESCRIPTION OF THE INVENTION Circuit for selective power supply to an electrical unit A supply voltage from an input feeder having a neutral conductor and a phase conductor is connected to a group of individual or parallel connected terminals. Circuits for selectively supplying the signals are well known. Each connection terminal includes a phase core and a non-polar core (neutral core), and an electric unit using electricity, such as a lighting fixture, is connected or connectable. Known circuits include a non-polar connection between a non-polar conductor and each non-polar core, and a phase connection between a phase conductor and each phase core. Further, as is well known, each phase core includes a switch that can switch between any associated electrical units or groups of associated electrical units. The end group of the switch / distribution device with the connected electrical unit is protected by an overcurrent protection element housed inside the switch / distribution device, the cutting surfaces of the phase core and the apolar core for the electrical unit are associated Suitable for overcurrent devices. Therefore, this means, in fact, that when a plurality of electrical units are connected to an end group, the cutting surface of the phase core for the electrical units is considerably larger. For example, 230V _~ A large number of lamps requiring 100 W of power are connected to the end group of switches and power distribution devices. The cross section of the phase core and the poleless core in which the relevant end group is installed is adapted for the overcurrent protection element of the end group in the switch / distribution device, the maximum allowable current being, for example, 16 A. Note that for comparison, the current of each of the 100 W lamps is less than 0.5 A. With respect to the circuit systems described above, there are microprocessor controlled switch systems that find use in various types of buildings. A first group of known systems is designed according to the decentralization principle, is mounted on a low ceiling, and has distributed control modules, power supply modules and switch modules to which electrical units such as luminaires can be individually connected. Including the set of These modules are interconnected using a set of data bus lines that are sequentially connected to a centrally located central control unit or CPU (Central Processing Unit). Here, the lighting operation is performed locally using a signal transmission medium or centrally using a control panel or a personal computer based on a computer program. A second group of known systems is likewise designed according to the principle of decentralization, where the control module and the power supply module are placed on the low ceiling mentioned above, and the switching device is integrated in an electrical unit, for example a luminaire. It is. Coupling and operation are performed as described above for the first group of known systems. A third group of known systems is designed according to the decentralization principle, where the control module is integrated in the switch unit and the power supply module and the switch module are located on the low ceiling mentioned above. Coupling and operation take place as described in the description for the first group of known systems. The system described above aims to simplify the installation of the system by reducing the amount of cables. The fourth and last group of systems is designed according to the centralization principle. However, these systems are rarely used. So far, the design of distributed structures has not been fully tested. Therefore, systems according to such principles, at the moment, already exist, are still too expensive. The three well-known decentralized systems described earlier have the following disadvantages. (1) Architects design buildings where they often use low ceilings. Some of these ceilings are movable and others are not. Architects always make decisions in practice in terms of the type of low ceiling that must be installed in the building. Here, the technical aspects play a minor role. Two types of low ceilings are used. That is, a so-called movable ceiling and a non-movable ceiling. In the case of movable ceilings, problems with decentralized facilities above the ceiling raise the problem that these ceilings must be officially moved by the building contractor. For this is the person responsible. In the case of non-movable ceilings (eg plaster ceilings), problems with decentralized facilities above such ceilings mean that they will be dismantled, and the cost may not be balanced. . In order to solve the problems associated with electrical installations, the users of these installations in these cases rely entirely on building contractors, which is an extremely unusual and highly undesirable situation. In the best case, the services to access the facilities deserve special attention. (2) When the control switch module is integrated with components such as a lighting device and a switch unit, there is a disadvantage in that it depends on manufacturing. When a special switch system is selected, the same manufacturer's instruments and switch units will always be utilized. This is incompatible with the desire to have the most freedom in choosing the manufacturer of the component to be installed, regardless of the manufacturer of the switch system to be selected. (3) A decentralized facility cannot be estimated after a certain period of time. Because, over the years, power supply and switch components may be added slowly but fairly randomly, and in fact the drawings and correction data have not been updated to the current situation. Furthermore, there is the disadvantage that the operation of such a system or the manner in which the various components are combined and interconnected is not clear to the user of the installation. This stems, inter alia, from the user's typical level of knowledge of such common "intelligent" components. The problem of serviceability also arises here. (4) The decentralized control module, the power supply module and the switch module can often be simply connected with the control lines of, for example, a bus cable input, a bus cable output, a power cable input, a switch line output, a signal transmission medium input, with great effort. Only. Such modules are also placed on the ceiling in large quantities, and the above operations must be performed for each module individually. Thus, many junctions result in cumbersome connections that are usually underestimated. (5) PLC (Programmable Logic Control) or microprocessor controlled intelligent control components, like computers, tend to be outdated, while equipment is depreciated over a long period of time, for example, on the order of 15 years. . What this means is that the equipment user needs to have the option of adapting the control engineering technology every few years to the new technology while maintaining the infrastructure. The entire installation must be modified with locally installed intelligent components, which is expensive. The conclusion that must be drawn from the five disadvantages mentioned above is that the control, power supply and switching devices must always be located in a position that is easily and freely accessible, so that service can be easily provided. It is. For example, in one or more technical fields, there is certainly only a fixed ceiling, not a low ceiling. The switch device and the control device must also be disconnectable, so that the control device can be easily replaced when desired, the simple centralized power supply, the switch and control wiring circuit must be improved. The installation design can be easily controlled. The entire equipment design must be documented for management. One object of the present invention is to improve the inherent security of the known circuit described above and to provide the option of mounting the circuit at a considerably reduced price. A second object of the invention is to make use of the module unit for individual requirements determined by the environment, with the possibility of easily adapting to new requirements after the circuit has been installed, It is an improvement of the known circuit so that it can be adapted very flexibly. A third object of the present invention is to make it easy to replace, replace, and monitor switch control parts, to considerably extend the effective service life of static parts including wiring parts and cable parts, and Designing the circuit so that it is easily adjustable. A fourth and final object of the present invention is to provide a switch circuit in which a sufficient synergy can occur between data control systems, switch technology, safety technology and energy distribution used as optional in the electrical unit. It is to materialize. For the above objects, the present invention provides an indoor power supply system for selectively supplying a supply voltage from an input feeder to individual or parallel connected terminals using apolar conductors, phase conductors and optionally a ground conductor. Provide a circuit. Each terminal is composed of a phase core, a non-polar core and a ground core as arbitrarily selectable, and an electric unit using electricity, such as a lighting device, can be connected thereto. The circuit includes a non-polar connection between the non-polar conductor and each non-polar core, a ground connection between each ground conductor and each ground core as an arbitrarily selectable one, A phase connection between the phase conductors and each phase core, located at the connection, and an overcurrent incorporated in each phase connection and limiting the current to a maximum current determined for the associated phase connection. It consists of a current safety element such as a fuse. It is noted here that at least one ground connection can optionally be added to this circuit. One example of such a circuit is embodied, for example, in that the current control element is, for example, a switch or a relay. A feature of another embodiment is that the current control element is a controller, such as a thyristor transistor. One very interesting possibility from a price point of view is that each phase core has a cutting surface adapted to the maximum current through the phase core. This deformation has the advantage that cores with fairly small cutting surfaces are generally sufficient, which leads to great advantages also in terms of mounting techniques, since thinner cores are easier to handle, and also a variety of cores There is also the possibility that the overall size of a bundle of can be reduced. Here, more core can be replaced through the mounting tube. Similarly, the present invention provides a variation in which each non-polar core comprises a cutting surface adapted to the maximum current through the non-polar core. One particular embodiment has the special feature that only the part between the overcurrent safety element and the associated terminal comprises a cutting surface adapted to the maximum current through the associated phase core. In an embodiment where certain advantages are obtained, in the circuit, a central control unit such as a switch panel, a PLC, a PC, for example, is programmed by a program present in the central control unit, for example, by external instructions, for example, a keyboard, a mouse, an optical sensor, It is adapted to control the current control element under program control using an operation based on a command from a warning sensor or the like. Such an embodiment results in great flexibility in combination with exceptionally easy operation. Preferably, the next embodiment consists of a circuit according to claim 1, wherein a number of currents controllable by a central control unit via individual control terminals and individual overcurrent safety elements connected in series to the control terminals. A housing for accommodating the control element, wherein a phase connection, a non-polar connection and an optionally selectable ground connection are connected together to respective poles of the first conductor, and the non-polar connection is A second connecting means connected to the second pole, the first connecting means being connectable to the input feed line, a number of phase cores, one non-polar core and optionally a ground core as second connecting means, e.g. Or a respective connection of the terminal strips, the second connection means being connectable to the terminals for the electrical unit, and a number of control terminals being provided by a third connection means, for example a connector or terminal strip. Are connected to respective poles of the lip, the third connecting means is connectable to the central control unit. In a special embodiment, the second and / or third connection means are fixedly connected to the housing. The circuit according to the invention described above preferably comprises bypass means for controlling the current control element without operation by the central control unit. This allows the system to be simply controlled via a bypass measure in case of emergency. The circuit with the central control unit is preferably provided with numerical values of various characteristics, e.g. total power, total power per group of terminals or total power with switches closed, number of hours the electrical unit is closed, For example, a monitor capable of presenting energy consumption during a predetermined period. The present invention also provides a module comprising a housing, wherein a number of current control elements that can be controlled by a central control unit via respective control terminals and overcurrent safety elements connected in series to the control terminals are provided in the housing. Related to the module placed inside. Furthermore, the invention relates to an electrical cable adapted to form part of a circuit according to the invention. Here, each phase core and each non-polar core comprise a cutting surface adapted to carry maximum current through the associated core. The electrical cable according to the invention comprises a number of insulated cores, each operating as a phase core, each having a relatively small cutting surface; Consisting of an insulating core with a relatively large cutting surface, acting as a solid ground core, and a jacket connecting and surrounding all the aforementioned cores. The present invention is further described with reference to the accompanying drawings. FIG. 1 shows a circuit diagram in a first embodiment according to the present invention. FIG. 2 shows a composite circuit diagram according to the present invention. FIG. 3 shows a microprocessor control circuit diagram according to the present invention. FIG. 4 is an example of a plan view of a hierarchy showing various lighting equipment. FIG. 5 is an example of a plan view of a layer showing a part of the low-voltage device. FIG. 6 is an example of a plan view of a hierarchy showing various signal media. FIG. 7A shows a top view of the DEPS module. FIG. 7B shows a front view of the DEPS module according to FIG. 7A. 8 to 17 show examples of detailed control current diagrams of the DEPS module. FIG. 18 shows an example of the terminal housing interceptor. FIG. 19 shows an example of the terminal housing input impedance. FIG. 20 shows an example of a schematic structure of equipment components showing various components shown in FIGS. 1 to 19. FIG. 21 shows an example of a data network structure having a predetermined structure. FIG. 22 shows a computer screen displaying a plan view using electric elements. FIG. 23 is an example of a wiring diagram of coupling of a signal medium. FIG. 24 shows an example of a wiring diagram in which a voltage output device is coupled to a DEPS module. FIG. 25 shows an example of a front view of a multi-unit panel having a number of DEPS modules and other devices, among others. FIG. 26 shows an example of a traffic light device according to the present invention. FIG. 27 shows an example of a traffic monitoring device according to the present invention. FIG. 28 shows a street light device according to the present invention. FIG. 29 shows a schematic diagram of an emergency power supply according to the present invention. FIG. 30 shows a schematic diagram of a sun protection device provided on a circuit board according to the present invention. FIG. 31 shows a schematic diagram of a door operating device provided on a circuit board according to the present invention. FIG. 32A shows a cross section of an electrical cable according to the present invention. FIG. 32B shows a side view of the end of such a cable. FIG. 33 shows a circuit diagram according to the invention including the electrical cable shown in FIG. 32 above. In the following description with reference to the accompanying drawings, the corresponding components are, where applicable, always denoted by the same reference numerals. FIG. 1 shows an example of a diagram of a simple control current of an electrical unit 1 connected by a central non-polar conductor 5 and an energized conductor 7 whose diameter is adapted to a fuse 44. The electric unit is switched by a manual switch 21. The entire device is connected to one end of a switch power distribution device 24, in which, for example, a group switch having a main fuse 22, a main energizing conductor 16, and a non-polar conductor 17 is provided. It should be noted that in FIG. 1 and many of the following figures, the cut surfaces of the various conductors are represented by relatively thick lines or relatively thin lines. This symbolically indicates that the thick line corresponds to a core having a relatively large cut surface, and the thin line corresponds to a core having a relatively small cut surface. It should also be noted that, in FIG. 1, the electrical units illustrated as lamps are connected from left to right as two groups of lights and individual lamps each connected in parallel. It will also be clear that any desired combination is possible in principle. FIG. 2 shows an example of a diagram of a more extensive control current of the electric unit 1. This electrical unit 1 can be switched remotely by using a relay 23 having a relay contact 4 which functions as a switch connected by a control current line 20 to a remotely located switch 21. The remote switch 21 can be manually operated, and is provided, for example, in a central operation panel. In FIG. 2, as in FIG. 1, the components are indicated by the same reference numbers. This applies to all drawings where applicable. FIG. 3 shows an example of a diagram of a complex control current of the electric unit 1 connected to a number of so-called DEPS modules (see FIG. 7). DEPS is an abbreviation for differential power switch. The various components of the module are shown in FIG. The D EPS module is connected to an end group of the switch / distribution device 24. The electrical unit can be activated by an output module 57, which is connected via a data signal cable 61 to a central processing unit CPU 59 having a personal computer 60 and / or a signal input device 56 having a signal medium. In this case, the pulse push button is connected using the control current signal cable 33. The electrical unit can be activated using a so-called splitter module 25, to which input voltage from the emergency control panel 10 and input voltage from the voltage output module 57 are applied together for interconnection with the DEPS module. Is done. The purpose of such a design is to use microprocessor technology and one or more emergency control panels to switch the electrical unit on and off. The emergency control panel and the voltage output module are interconnected via one or more splitter modules 25 via a control current cable 63, and are connected to the connector chassis 43 (FIG. 7) of the DEPS module. FIG. 4 shows an example of a hierarchical plan view of various lighting installations 1 which are fixedly or detachably connected by electrical connection means to a DEPS module 2 shown and described below with reference to DEPS. By assembling the lighting fixtures indicated by boundary 3, they can be connected to each other. FIG. 4 also shows an example of a relay contact cord 4 to which a lighting installation can be connected behind. 5 and 6 are other plan views with the mounting device forming part of FIG. FIG. 5 is an example of a hierarchical plan view illustrating a part of the low-voltage device. This figure shows a non-polar conductor 5 and a ground conductor 6, to which a set of electrical units, in this case lighting equipment, can be connected. In order to supply voltage to the lighting installation, the switched conducting conductors 7 must be able to be separated and branched, for which purpose they are connected to an interceptor (see FIG. 18) which is a terminal housing. And connected to an equivalent DEPS module (see FIG. 7) in the multi-unit panel (see FIG. 25) using the ground conductors 5 and 6. The lighting installation is fixedly connected to the connection point 13 via a phase conductor and a non-polarized / grounded conductor 14, or connected to the socket 12 by a cable and a plug. The lighting installation can also be switched outside the control system by using an emergency control panel 10 supplied via a power supply 11. The arrangement of the lighting equipment is referred to with reference to FIG. The arrangement of the DEPS modules indicated by reference numerals DPS-1304 and DPS1305 is arranged and configured as an example. A floor plan including the mounting equipment forming part of FIG. 5 is illustrated in FIGS. 4 and 6. Unit 25 is an example of a splitter module. The input voltage from the emergency control panel 10 having the integrated power supply unit 11 and the input voltage from the voltage output unit 57 are combined at the splitter module to interconnect with the DFPS module. The purpose of this structure is to switch the electrical unit on and off via the emergency control panel using the central control unit. FIG. 6 is an example of a plan view of all rooms on the same floor showing various signal media, such as a passive infrared (PIR) detector 28, a pulse push button 29, an infrared transmitter 30, and an infrared receiver 31. These signal media are coupled to an input module. This input module can be housed in a multi-unit panel (see FIG. 25). The multi-unit panel may or may not be connected via a terminal housing “input interface” (see FIG. 19) that is coupled to the input module via a signal cable 33. A floor plan including the installation of FIG. 6 is illustrated in FIGS. 7A and 7B relate to an example of a DEPS module comprising the following components: It comprises a housing 40 containing various components, a mains connection device 41, a non-polar and a ground conductor 42, a conductor connection component for operating the relay coil 43 at an input voltage, a conductor from overcurrent, A fuse or other type of current limiting / current protection means 44 for protecting the relay contacts or the electric unit, respectively; an operation switch for setting the voltage and current to zero for the DEPS module 45; This is a warning device for protecting the device. The remaining components form the mounting means 48. The structure according to FIG. 7 is organized with the above components. However, other types of relays, voltage converters, and voltage regulators may be used for certain applications that use a distribution structure as described above. 8 to 17 are examples of detailed control current diagrams of the DEPS module. In these figures, except for the anti-sabotage parts 46 and 47, the components of FIG. 7 can be found. FIG. 18 contains an “interceptor” having components, such as a housing 49 having terminals 50 for conductors carrying current, terminals for pole / ground 51 and mounting means 52. It is an example of a terminal. Due to the mounting means 52, the discrete wiring / cables become bundled wiring / cables. FIG. 19 is an example of a terminal housing an "input interface" having components such as a housing 53 having terminals 54 and mounting means. Due to the mounting means, the discrete wiring / cables become bundled wiring / cables. FIG. 20 shows a signal input device 56, a control voltage output unit 57, a power supply unit 58 for supplying power to the units 56 and 57, a central processing unit 59 for operating the system according to a program, and an integrated computer system. 60, a data cable 61, a power supply voltage cable 62, a control voltage cable 63, a cable for optional sabotage contacts 64, and a cable for transmitting data via the telephone network 66, as described above. FIG. 20 is an example of a schematic structure of an installation component showing components as shown in FIGS. FIG. 21 is an example of the data network structure of a particular building 65, where the components described in the above figures can be found. FIG. 22 shows a computer monitor. A plan view (FIG. 4) of a floor including an electric unit, in this case, lighting equipment, is displayed on the monitor. This monitor can be used to switch the electrical unit on and off. This is because the monitor is coupled to a computer having a computer program and a data network as illustrated in the figure above. FIG. 23 is an example of a wiring diagram of the coupling between the signal medium and the signal input means represented by reference numerals 28, 29 and 31 via the “input interface” (see FIG. 19). FIG. 24 is an example of a wiring diagram of the connection between the voltage output unit 57 and the DEPS module (see FIG. 7). FIG. 25 is an example of a multi-unit panel. The multi-unit panel contains, in particular, the following components. It is a DEPS module (FIG. 7), a splitter module 25, a signal input unit 56, a voltage output unit 57, a power supply unit 58 and other mounting means. FIG. 26 shows a schematic structure which is an application example of a system having a DEPS module for a traffic signal device. FIG. 26 also shows the following components in addition to the components already described. It is a traffic detection loop 67, a pulse push button 68 for pedestrians and cyclists, and a traffic signal 69. FIG. 27 shows a schematic structure with DEPS for a traffic monitoring device. FIG. 27 shows the following components in addition to the components already described. It is a traffic sign 68, 72, 73 that includes a traffic detection loop 67, a speed detector 70, a fog detector 71, and a fog indicator 73. FIG. 28 shows a schematic structure having a DEPS module for public road lighting equipment. FIG. 28 also shows, in particular, the following components: It is a traffic detection loop 67, a motion detector 74, a dimmer switch 75, and a traffic lamp post 76. The design and installation of this device can be performed quickly and reliably in a very controllable way with respect to the structure and the considered structure. Step 1 : Determine the positions of the attachment point and the connection point (see FIG. 4); Step 2 : Design the equipment diagram including the symbols by aligning the switch module information (for example, see FIG. 5); Step 3 : After programming, design the equipment diagram (see Figs. 5 and 6); Step 4 : Assembling an empty multi-unit panel (see FIG. 25 including components); Step 5 ： Create according to the equipment diagram, arrange and connect multi-unit panels; Step 6 : Enter the dimension data in the information format for the switch module; Step 7 : At the factory, assemble the module and program the input / output computer system; Step 8 : Immediately before delivery, arrange various modules and insert connectors. The operation of the entire apparatus can be performed by a computer having peripheral devices as described below. When you start your computer and log in, the menu appears next. Next, a list appears on the screen asking which building aggregate you are interested in. By typing or selecting the relevant information, a plan view of the determined aggregate appears. In this plan view, an arrow pointing north can be shown, associating the location of the assembly with its surroundings. The above building is shown on this plan view. By selecting a building here, a side view of the building with a direction indication appears. Here, various side views of the building can be drawn. Various floors are shown in the side view. For example, the lighting switch can be closed by clicking on a space on the side of the building. For example, this displays a promotional campaign to the surroundings. Here, it is also possible to pre-program a particular promotional campaign, so that a particular image can be displayed automatically at any desired time. However, if, for example, it is necessary to turn on or off the lighting switch of one or more floors, or to see its status, this floor can be clicked on for this purpose, thereby providing a plan view of the relevant floor Appears. Other operations can also be performed, such as, for example, operating a socket, blinds, electrically lockable or unlockable doors, and the like. Therefore, this is a multifunctional system. On a plan view, the electrical unit can be switched on or off by clicking on it or selecting its group. It is also possible to operate a complete safety device with a DEPS control system. Therefore, the control system can be used multifunctionally. It is also possible to provide the system with several forms of information related to the status of the device, for example: That is, the number of lighting fixtures that are switched on in the building group, per building, per floor, per exterior wall. Switch-on power of electrical units in a group of buildings, per building, per floor, per exterior wall. Energy consumption per hour, per day, per month, per year, per building, per floor, per outer wall. By storing various kinds of information related to the user's device in the memory of the central control unit, it is possible to draw a diagram showing the features with a simple specification. The control or switch devices in the multi-unit panel are located at various locations and function as autonomous devices. Therefore, even if the central control unit fails, the operation can be continued locally. If the device is connected to the international telephone network and the data connection is good, basically remote control is possible, so that the device on the user's side can use a computer from any location in the world. Can operate. This can be done in particular based on ISDN telephone lines. The lighting operation can also be performed according to the user's wishes, for example pulse push buttons in the office, a group of control pulse push buttons in the department (couplings with card reader, PIR (passive infrared) detection). It can also be done by local switching media, such as an infrared controller using a device, etc. These signaling media are locally coupled to the associated input cards, which are further connected via output cards. In the event of an operating system failure or during a maintenance operation, the electrical unit is switched outside the system using one or more emergency control panels powered by the power supply unit. The emergency control panel connects the splitter module 25 with a multi-core cable. The system according to the invention can be applied to any type of building, such as utility buildings, health care buildings, dwellings, etc., as well as to traffic lighting devices, traffic It has been found that it is also applicable to public electrical units, such as surveillance systems and road lighting devices, etc., see in particular Figures 26, 27 and 28. Figures 29 and 28 described below. 30 and 31 relate to an emergency power supply, a solar protection device and a door operation system, etc. Fig. 29 is a multi-unit panel with a switch / distribution device 80 and / or a non-interrupting unit 9 (Fig. 25). ) And the interconnected DEPS devices (FIGS. 20, 26, 27, 28, 0, see also FIG. 31), which comprises a switch / distribution device comprising a cooperating control / switch box 79 from a transformer 77 connected to the utility mains. And an emergency power generation set 78. Reference numeral 82 designates a feed line for devices in a multi-unit panel (FIG. 25), also in this embodiment also via a non-interrupting unit 9. When the voltage on the utility energy mains drops significantly, a signal is sent via signal line 81 to the control and switch box 79 to switch on the emergency power generation set and is switched. Sent to the DEPS device to switch off the electrical unit, if the emergency power generation set is switched to the switch / distribution device, the electrical unit will automatically Or manually, by selecting a preset, it is selectively switched to an emergency power generator sets. Here, a central processing unit (CPU) 59 is used, which includes a signal line 61, a computer 60, an emergency power generation set control / switch box 79, and an input / output module in a multiplex unit panel (FIG. 25). 56 and 57. FIG. 30 is a schematic view of a solar radiation protection device to which the DEPS module is applied. In this example, the following components are used in addition to the above components. A blind control motor 84 for raising and lowering the blinds, shades and the like, and an end for stopping the blind control motor at the end of the travel. A section switch 85 and a sunshade blind operation switch 83 are used. FIG. 31 is a schematic diagram of a door operating device including a DEPS module. Here, the following components are further used. That is, a door operation push button 86 for unlocking an electrically controllable door lock 86, a signal line 87 connected to the input module 56 for locking, a bolt, and a door position indicator are used. ing. The transformer 89 supplies a low voltage of, for example, 24 V for electromagnetic control of the lock in question, for example by using a solenoid with a movable core therein. FIGS. 32 and 33 show an example of an electrical cable according to the invention and an application with an arrangement corresponding to FIG. 2, respectively. FIG. 32 shows a multi-core electrical cable with a group of multiple current conductors, indicated at 101, 102 and 103, which are electrically insulated from each other by separate insulating sheaths. FIG. 32 also shows that the non-polar core 101 and the ground core 102 have a larger diameter than the phase core 103. In this embodiment, the cable 120 is assumed to be placed underground. For this purpose, in this embodiment, a metal reinforcing member 105 is provided, but the reinforcing member 105 can be omitted in other application forms. The insulating sheath of the individual cores is indicated by reference numeral 104. A collective armor that collectively holds and covers the core bundle is shown at 124. FIG. 33 shows an application form of the cable 120 in an electric circuit as in the case of FIG. Here, the electric unit is the lighting device 126 in this case, but a voltage is supplied from the switch module 127 integrated with the following components. That is, the fuse 44 for overcurrent, the relay 23 with the switching contact 4, and the connector chassis portion 42 (see also FIG. 3) are integrated. The cable illustrated in FIG. 32 is connected to the connector 42 using the connector 212. The relay 23 is driven by the switch 21 connected to the connector chassis 43 on the DEPS module by the control current core 20 bundled in the cable 214. The electric unit 126 and the DEPS module 127 are supplied with voltage from a terminal group of the switch / distributor 24. This device is provided with a group switch having a main fuse 22 for protecting the cores 130, 131, 131 of the power supply cable 133 from overcurrent. Safety devices 22 and 44 are mutually selective, as will be apparent from the foregoing description of the principles of the invention.

────────────────────────────────────────────────── ─── Continuation of front page    (81) Designated countries EP (AT, BE, CH, DE, DK, ES, FI, FR, GB, GR, IE, IT, L U, MC, NL, PT, SE), OA (BF, BJ, CF) , CG, CI, CM, GA, GN, ML, MR, NE, SN, TD, TG), AP (GH, GM, KE, LS, M W, SD, SZ, UG, ZW), EA (AM, AZ, BY) , KG, KZ, MD, RU, TJ, TM), AL, AM , AT, AU, AZ, BA, BB, BG, BR, BY, CA, CH, CN, CU, CZ, DE, DK, EE, E S, FI, GB, GE, GH, GM, GW, HU, ID , IL, IS, JP, KE, KG, KP, KR, KZ, LC, LK, LR, LS, LT, LU, LV, MD, M G, MK, MN, MW, MX, NO, NZ, PL, PT , RO, RU, SD, SE, SG, SI, SK, SL, TJ, TM, TR, TT, UA, UG, US, UZ, V N, YU, ZW

Claims (1)

[Claims] 1. Polarized conductors, phase conductors and optional grounding Terminals to connect the power supply voltage from the input power line individually or in parallel using the conductor A home circuit for selectively supplying a group, wherein each terminal has a phase core, a non-polar core, and an optional core. An electrical unit that uses electricity, consisting of a ground core For example, lighting equipment can be connected,   A non-polar connection between the non-polar conductor and each non-polar core,   An optional ground connection between each ground conductor and each ground core With the connection,   The phase conductor and the respective phase, wherein a phase control element is arranged at the phase connection A phase connection between the core and   Maximum current built into each phase connection and determined for the associated phase connection An overcurrent safety element, such as a fuse, that limits the current to   Circuit consisting of 2. In the circuit according to claim 1, the current control element is, for example, a switch or A circuit that is a relay. 3. In the circuit according to claim 1, the current control element is a controller, for example. A circuit that is a thyristor transistor. 4. 2. The circuit according to claim 1, wherein each phase core has a first phase core. A circuit with a cutting surface adapted for large currents. 5. 2. The circuit according to claim 1, wherein each of the non-polar cores passes through the non-polar core. A circuit with a cutting surface adapted for large currents. 6. 2. The circuit according to claim 1, wherein each of the overcurrent safety elements includes a phase conductor. Circuit located in the associated phase connection, close to the 7. The circuit according to claim 1, wherein the terminal is between the overcurrent safety element and a related terminal. Only a section of the device has a cutting surface adapted to the maximum current through the relevant phase core circuit. 8. The circuit according to claim 1, wherein a central control unit such as a switch panel, a PLC, and a PC is provided. If the control unit is, for example, External instructions, such as keyboards, mice, light sensors, and warning sensors Controls the current control element based on program control using operations based on commands A circuit that is adapted to 9. In the circuit according to claim 1, each control terminal and each control terminal are connected in series. Multiple controllable by the central control unit via individual overcurrent safety elements connected A housing for accommodating a number of current control elements,   Phase connections, non-polar connections and optionally selectable ground connections are the first Each pole of the conductor is connected together, and the non-polar connection is connected to the second connection of the first connection means. The first connection means is connectable to the input power supply line,   Multiple phase cores, one non-polar core and optionally optional grounded core Are connected to respective poles of a second connection means, such as a connector or a terminal strip. , The second connection means is connectable to a terminal for the electrical unit,   Multiple control terminals are connected by third connection means, such as a connector or terminal strip And the third connection means is connectable to the central control unit. Circuit. 10. 10. The circuit according to claim 9, wherein the first, second and / or third connection means. Is fixedly coupled to the housing. 11. 9. A circuit as claimed in claim 8, without operation by a central control unit. And a circuit comprising a bypass means for controlling the current control element. 12. 9. The circuit according to claim 8, wherein various numerical values of the characteristic, for example, Power, total power per group of terminals or total power with switch closed, electrical unit The number of hours the unit is closed and the energy consumption over a fixed period can be presented A circuit provided with a presentation means such as a monitor. 13. A module comprising the housing according to claim 9,   Via each control terminal and an overcurrent safety element connected in series to the control terminal Numerous current control elements that can be controlled by a central control unit are located in the housing Module to be executed. 14． An electrical cable adapted to form part of a circuit according to claims 4 and 5. Table,   Numerous insulating cores each acting as phase cores, each with a relatively small cutting surface A and   An insulating core that operates as a non-polar core and has a relatively large cutting surface;   Operates as an optional grounding core and has a relatively large cutting surface An insulating core comprising:   A jacket that connects and surrounds all the aforementioned cores   Cable consisting of.